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Recovering samples for ancient DNA research—guidelines for the field archaeologist

Published online by Cambridge University Press:  22 April 2026

Morten E. Allentoft
Morten E. Allentoft*
Affiliation:
Centre for GeoGenetics, Natural History Museum, University of Copenhagen, Østervoldgade 5–7, DK-1350, Copenhagen, Denmark
*
(Email: Morten.Allentoft@gmail.com)

Abstract

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Information

Type
Rapid Communication
Information
Antiquity Project Gallery , Volume 87 , Issue 338 , December 2013 , pp. 1 - 4
Copyright
Copyright © The Author(s), [2013]. Published by Cambridge University Press on behalf of Antiquity Publications Ltd.

Introduction

Ancient DNA represents a direct window to study evolutionary processes of the past. The information stored in these ancient biomolecules can provide insights into, for example, migrations and colonisation events of early humans (Haak et al. 2010; Rasmussen et al. 2011), phylogenetic relationships of extinct species (Shapiro et al. 2002; Bunce et al. 2009), the taxonomic composition of ancient ecosystems (Willerslev et al. 2003; Hebsgaard et al. 2009), or uncover individual phenotypic traits like eye colour, skin colour or diseases (Rasmussen et al. 2010; Keller et al. 2012), which are not preserved in ancient remains. Numerous studies in recent years have documented the prolific scientific synergisms occurring in the overlap between molecular biology, archaeology and palaeontology.

Working with ancient and degraded DNA is not without challenges. Most serious perhaps is the risk of contamination with contemporary DNA, which can easily 'swamp' the small amount of authentic DNA in an ancient sample. This fact became painfully clear in the earlier years of ancient DNA research, when a number of high profile publications seemingly presented evidence of DNA from samples of extreme age—including 80-million-year-old dinosaur bones (Woodward et al. 1994) and >120-million-year-old insects (Cano et al. 1993). We are now aware that these results reflected modern contaminants (reviewed in Willerslev & Cooper 2005), in part because the rate of post mortem fragmentation of DNA excludes the existence of DNA that old (Allentoft et al. 2012). In response to these claims, a set of ancient DNA 'rules' was established to minimise the risk of contamination and to provide some means for downstream authentication of the results (Cooper & Poinar 2000; Gilbert et al. 2005a) and, since then, numerous studies have identified and assessed contamination problems in ancient samples (e.g. Gilbert et al. 2005b; Malmström et al. 2005; Yang & Watt 2005; Pilli et al. 2013).

In essence, however, most of these rules represent 'symptomatic treatment'. If a sample is contaminated with modern DNA before entering the laboratory, for example during excavation, it can be difficult to remove the contamination, and it can be impossible to distinguish between authentic ancient DNA and contaminants. This latter problem is particularly pertinent if the target DNA and the contaminant DNA are from the same species, as is often the case when research is conducted on ancient human material.

In the era of high-throughput sequencing, statistical tools based on DNA damage signatures are now available to assess the overall authenticity of 'bulk' ancient DNA data (Ginolhac et al. 2011). Considerable time and resources, however, are expended before the contamination can be identified, and if a sample has been contaminated decades or centuries ago it may result in contaminant DNA that displays degradation damage patterns similar to that of true ancient DNA (short fragments and an increase in C to T or G to A base changes close to the end of the sequences) (Sampietro et al. 2006; Garcia-Garcera et al. 2011). Although strict laboratory exercises are often combined with bioinformatic analyses to respectively remove and identify DNA contamination, it would be extremely beneficial if the risk of contamination could be lowered in the first place.

In addition to contamination risks it is relevant to consider the negative impacts on DNA preservation that can happen in a specimen after excavation. It has been demonstrated that DNA in bone, to a greater (Pruvost et al. 2007) or lesser extent (Allentoft et al. 2012), will degrade faster when it is removed from its preservation environment. Even the most powerful sequencing technology is useless when the DNA strand is completely disintegrated, so an excavated specimen must be treated carefully to minimise this expected increase in molecular decay.

Below are listed five simple rules that can be implemented during an archaeological excavation to increase the potential for downstream ancient DNA analyses. They are not novel per se, since somewhat similar guidelines can be found in previous articles, or as part of more comprehensive ancient DNA guidelines (e.g. Reference BrownBrown 1998; Yang & Watt 2005; Brown & Reference Brown and BrownBrown 2011; Matisoo-Smith & Horsburgh 2012). Arguably, however, these are the five most crucial rules that should be applied to maintain the molecular integrity of ancient samples. Equally important for the field archaeologist, these five rules are easy to implement by default at any given excavation (DNA or non-DNA focused) with a minimum of preparation and delay. I note that the five rules represent minimum requirements but there are other aspects to consider. If preparing for an excavation that is specifically aimed at recovering material for ancient DNA analyses, it would be beneficial to consult more detailed literature on this subject.

The five rules

  1. Minimise the time between initial exposure (discovery) and removal of the specimen from the sediment. If, for recording purposes, the specimen must remain a little while in situ, it can be covered with plastic until removed.

    Reason: the DNA contamination risk increases when a specimen is exposed.

  2. Handle the specimen with plastic gloves, and wear disposable sleeves and a face mask. If any tools are used to extract/remove the specimen from the sediment these should be sterilized in 10 per cent hypocholorite before use.

    Reason: these procedures will minimise the risk of contamination from modern human DNA.

  3. Place the specimen in a zip-lock plastic bag or other sterile container. If it is subsequently necessary to take out the sample for further examination, wear gloves, disposable sleeves and a face mask.

    Reason: as above.

  4. Keep the specimen cold and dry (preferably frozen) until the molecular work can be carried out at a dedicated ancient DNA facility. Never wash the specimen and/or leave it to dry in the sun.

    Reason: heat and humidity will increase the rate of pure chemical DNA fragmentation (hydrolysis and oxidation) as well as microbially facilitated DNA degradation (enzymatic).

  5. Minimise the time period from excavation to DNA extraction.

    Reason: in general, the DNA degrades faster in a sample no longer in situ.

Concluding remarks

A trained ancient DNA researcher will by default assume that any given sample is contaminated with modern DNA and will therefore treat it accordingly. An implementation of the above guidelines should not change that practice. Nonetheless, if more caution is exercised in both the field during excavation, and later during cataloguing and storage, the proportion of recovered specimens that display a molecular scientific value should increase significantly.

Acknowledgements

I would like to thank Professor Terry Brown and Professor Lisa Matisoo-Smith for constructive comments on an earlier version of the manuscript. The author is funded by the Danish National Research Foundation, the European Research Council under the European Union's 7th Framework Programme: ERC Grant Agreement no. 269442 (THE RISE), and Marie Curie Actions, Grant Agreement no. 300554.

References

Allentoft, M.E., Collins, M., Harker, D., Haile, J., Oskam, C.L., Hale, M.L., Campos, P.F., Samaniego, J.A., Gilbert, M.T.P., Willerslev, E., Zhang, G., Scofield, R.P., R.N. Holdaway & M. Bunce. 2012. The half-life of DNA in bone: measuring decay kinetics in 158 dated fossils. Proceedings of the Royal Society B: Biological Sciences 279: 4724–33. Google Scholar
Brown, K. 1998. Keeping it clean: the collection and storage of ancient DNA samples from the field. The Archaeologist 33: 16–17. Google Scholar
Brown, T. & Brown, K.. 2011. Biomolecular archaeology: an introduction. Chichester: Wiley-Blackwell. CrossRefGoogle Scholar
Bunce, M., Worthy, T.H., Phillips, M.J., Holdaway, R.N., Willerslev, E., Haile, J., Shapiro, B., Scofield, R.P., Drummond, A., P.J.J. Kamp & A. Cooper. 2009. The evolutionary history of the extinct ratite moa and New Zealand Neogene paleogeography. Proceedings of the National Academy of Sciences of the USA 106: 20646–51. Google Scholar
Cano, R.J., Poinar, H.N., Pieniazek, N.J., A. Acra & G.O. Poinar. 1993. Amplification and sequencing of DNA from a 120–135-million-year-old weevil. Nature 363: 536–38. Google Scholar
Cooper, Poinar. 2000. Ancient DNA: do it right or not at all. Science 289: 1139Google ScholarPubMed
Garcia-Garcera, M., Gigli, E., Sanchez-Quinto, F., Ramirez, O., Calafell, F., S. Civit & C. Lalueza-Fox. 2011. Fragmentation of contaminant and endogenous DNA in ancient samples determined by shotgun sequencing; prospects for human palaeogenomics. PLOS ONE 6(8): e24161. 10.1371/journal.pone.0024161 Google Scholar
Gilbert, M.T.P., Bandelt, H.J., M. Hofreiter & I. Barnes. 2005a. Assessing ancient DNA studies. Trends in Ecology & Evolution 20: 541–44. Google Scholar
Gilbert, M.T.P., Rudbeck, L., Willerslev, E., Hansen, A.J., Smith, C., Penkman, K.E.H., Prangenberg, K., Nielsen-Marsh, C.M., Jans, M.E., Arthur, P., Lynnerup, N., Turner-Walker, G., Biddle, M., B. Kjolbye-Biddle & M.J. Collins. 2005b. Biochemical and physical correlates of DNA contamination in archaeological human bones and teeth excavated at Matera, Italy. Journal of Archaeological Science 32: 785–93. Google Scholar
Ginolhac, A., Rasmussen, M., Gilbert, M.T.P., E. Willerslev & L. Orlando. 2011. mapDamage: testing for damage patterns in ancient DNA sequences. Bioinformatics 27: 2153–55. Google Scholar
Haak, W., Balanovsky, O., Sanchez, J.J., Koshel, S., Zaporozhchenko, V., Adler, C.J., Sarkissian, C., Brandt, G., Schwarz, C., Nicklisch, N., Dresely, V., Fritsch, B., Balanovska, E., Villems, R., Meller, H., Alt, K.W., A. Cooper & C. Genographic. 2010. Ancient DNA from European Early Neolithic farmers reveals their Near Eastern affinities. PLOS Biology 8(11): e1000536. 10.1371/journal.pbio.1000536 Google Scholar
Hebsgaard, M.B., Gilbert, M.T.P., Arneborg, J., Heyn, P., Allentoft, M.E., Bunce, M., Munch, K., C. Schweger & E. Willerslev. 2009. 'The Farm Beneath the Sand'—an archaeological case study on ancient 'dirt' DNA. Antiquity 83: 430–44. Available at http://antiquity.ac.uk/ant/083/ant0830430.htm Google Scholar
Keller, A., Graefen, A., Ball, M., Matzas, M., Boisguerin, V., Maixner, F., Leidinger, P., Backes, C., Khairat, R., Forster, M., Stade, B., Franke, A., Mayer, J., Spangler, J., Mclaughlin, S., Shah, M., Lee, C., Harkins, T.T., Sartori, A., Moreno-Estrada, A., Henn, B., Sikora, M., Semino, O., Chiaroni, J., Rootsi, S., Myres, N.M., Cabrera, V.M., Underhill, P.A., Bustamante, C.D., Vigl, E.E., Samadelli, M., Cipollini, G., Haas, J., Katus, H., O'connor, B.D., Carlson, M.R.J., Meder, B., Blin, N., Meese, E., C.M. Pusch & A. Zink. 2012. New insights into the Tyrolean Iceman's origin and phenotype as inferred by whole-genome sequencing. Nature Communications 3: article no. 689. 10.1038/ncomms1701 Google Scholar
MalmstrÖm, H., Stora, J., Dalen, L., G. Holmlund & A. Gotherstrom. 2005. Extensive human DNA contamination in extracts from ancient dog bones and teeth. Molecular Biology and Evolution 22: 2040–47 Google Scholar
Matisoo-Smith, E. & Horsburgh, K.A.. 2012. DNA for archaeologists. Walnut Creek (CA): Left Coast. Google Scholar
Pilli, E., Modi, A., Serpico, C., Achilli, A., Lancioni, H., Lippi, B., Bertoldi, F., Gelichi, S., M. Lari & D. Caramelli. 2013. Monitoring DNA contamination in handled vs. directly excavated ancient human skeletal remains. PLOS ONE 8(1): e52524. 10.1371/journal.pone.0052524 Google Scholar
Pruvost, M., Schwarz, R., Correia, V.B., Champlot, S., Braguier, S., Morel, N., Fernandez-Jalvo, Y., T. Grange & E.M. Geigl. 2007. Freshly excavated fossil bones are best for amplification of ancient DNA. Proceedings of the National Academy of Sciences of the USA 104: 739–44, J. WANG & E. WILLERSLEV. Google Scholar
Rasmussen, M., Li, Y.R., Lindgreen, S., Pedersen, J.S., Albrechtsen, A., Moltke, I., Metspalu, M., Metspalu, E., Kivisild, T., Gupta, R., Bertalan, M., Nielsen, K., Gilbert, M.T.P., Wang, Y., Raghavan, M., Campos, P.F., Kamp, H.M., Wilson, A.S., Gledhill, A., Tridico, S., Bunce, M., Lorenzen, E.D., Binladen, J., Guo, X.S., Zhao, J., Zhang, X.Q., Zhang, H., Li, Z., Chen, M.F., Orlando, L., Kristiansen, K., Bak, M., Tommerup, N., Bendixen, C., Pierre, T.L., Gronnow, B., Meldgaard, M., Andreasen, C., Fedorova, S.A., Osipova, L.P., Higham, T.F.G., Hansen, T.V.O., Nielsen, F.C., Crawford, M.H., Brunak, S., Sicheritz-Ponten, T., Villems, R., Nielsen, R., Krogh, A., J. Wang & E. Willerslev. 2010. Ancient human genome sequence of an extinct Palaeo-Eskimo. Nature 463: 757–62. Google Scholar
Rasmussen, M., Guo, X.S., Wang, Y., Lohmueller, K.E., Rasmussen, S., Albrechtsen, A., Skotte, L., Lindgreen, S., Metspalu, M., Jombart, T., Kivisild, T., Zhai, W.W., Eriksson, A., Manica, A., Orlando, L., Tridico, S., Metspalu, E., Nielsen, K., Avila-Arcos, M.C., Moreno-Mayar, J.V., Muller, C., Dortch, J., Gilbert, M.T.P., Lund, O., Wesolowska, A., Karmin, M., Weinert, L.A., Wang, B., Li, J., Tai, S.S., Xiao, F., Hanihara, T., Jha, A.R., Ricaut, F.X., Migliano, A.B., Romero, I.G., Kristiansen, K., Lambert, D.M., Brunak, S., Forster, P., Brinkmann, B., Nehlich, O., Bunce, M., Richards, M., Gupta, R., Bustamante, C.D., Krogh, A., Foley, R.A., Lahr, M.M., Balloux, F., Sicheritz-Ponten, T., Villems, R., Nielsen, R., J. Wang & E. Willerslev. 2011. An Aboriginal Australian genome reveals separate human dispersals into Asia. Science 334: 94–98. Google ScholarPubMed
Sampietro, M.L., Gilbert, M.T.P., Lao, O., Caramelli, D., Lari, M., J. Bertranpetit & C. Lalueza-Fox. 2006. Tracking down human contamination in ancient human teeth. Molecular Biology and Evolution 23: 1801–1807. Google Scholar
Shapiro, B., Sibthorpe, D., Rambaut, A., Austin, J., Wragg, G.M., Bininda-Emonds, O.R.P., P.L.M. Lee & A. Cooper. 2002. Flight of the dodo. Science 295: 1683 . Google Scholar
Willerslev, E. & Cooper, A.. 2005. Ancient DNA. Proceedings of the Royal Society B: Biological Sciences 272: 3–16. Google Scholar
Willerslev, E., Hansen, A.J., Binladen, J., Brand, T.B., Gilbert, M.T.P., Shapiro, B., Bunce, M., Wiuf, C., D.A. Gilichinsky & A. Cooper. 2003. Diverse plant and animal genetic records from Holocene and Pleistocene sediments. Science 300: 791–95. Google Scholar
Woodward, S.R., N.J. Weyand & M. Bunnell. 1994. DNA-sequence from Cretaceous period bone fragments. Science 266: 1229–32. Google Scholar
Yang, D.Y. & Watt, K.. 2005. Contamination controls when preparing archaeological remains for ancient DNA analysis. Journal of Archaeological Science 32: 331–36. Google Scholar